This paper presents the self-stabilisation features of a hopping gait during underwater legged locomotion. We used a bio-inspired fundamental model of this gait, the underwater spring-loaded inverted pendulum model, to numerically derive quantitative (dimension of the basin of attraction, Floquet multipliers, mean horizontal speed) and qualitative (shape of the basin) features which characterise the self-stability of the system. Furthermore, we compared the results obtained with a terrestrial self-stable running model (i.e. the spring-loaded inverted pendulum with swing-leg retraction) to highlight the role of water-related components in relation to dynamic legged locomotion. The analysis revealed fundamental morphological and actuation par...
In aquatic pedestrian locomotion the dynamics of terrestrial and aquatic environments are coupled. H...
In aquatic pedestrial locomotion, the dynamics of terrestrial and aquatic environments are coupled. ...
In this research, the dynamic walking of a legged robot in underwater environments is proposed. For ...
This paper presents the self-stabilisation features of a hopping gait during underwater legged locom...
In this letter, a fundamental model for underwater legged locomotion, called U-SLIP, is presented an...
For robots to navigate successfully in the real world, unstructured environment adaptability is a pr...
In this paper a model-based open loop control of SILVER, a multigait legged underwater vehicle for t...
In this work a punting gait model, describing a robot running underwater, is studied with respect to...
Bioinspired legged locomotion is attractive for underwater applications that involve moving in unstr...
In recent years a number of robotic platforms have been developed, that are capable of robust locomo...
Drawing inspiration from the locomotion modalities of animals, legged robots demonstrated the potent...
This paper studies underwater legged locomotion (ULL) by means of a robotic octopus-inspired prototy...
In aquatic pedestrian locomotion the dynamics of terrestrial and aquatic environments are coupled. H...
In aquatic pedestrial locomotion, the dynamics of terrestrial and aquatic environments are coupled. ...
In this research, the dynamic walking of a legged robot in underwater environments is proposed. For ...
This paper presents the self-stabilisation features of a hopping gait during underwater legged locom...
In this letter, a fundamental model for underwater legged locomotion, called U-SLIP, is presented an...
For robots to navigate successfully in the real world, unstructured environment adaptability is a pr...
In this paper a model-based open loop control of SILVER, a multigait legged underwater vehicle for t...
In this work a punting gait model, describing a robot running underwater, is studied with respect to...
Bioinspired legged locomotion is attractive for underwater applications that involve moving in unstr...
In recent years a number of robotic platforms have been developed, that are capable of robust locomo...
Drawing inspiration from the locomotion modalities of animals, legged robots demonstrated the potent...
This paper studies underwater legged locomotion (ULL) by means of a robotic octopus-inspired prototy...
In aquatic pedestrian locomotion the dynamics of terrestrial and aquatic environments are coupled. H...
In aquatic pedestrial locomotion, the dynamics of terrestrial and aquatic environments are coupled. ...
In this research, the dynamic walking of a legged robot in underwater environments is proposed. For ...